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MINISTRY OF SCIENCE AND TECHNOLOGY DEPARTMENT OF TECHNICAL AND VOCATIONAL EDUCATION SAMPLE QUESTIONS & WORKED OUT EXAMPLE For EP-02011 ELECTRICAL ENGINEERING CIRCUIT ANALYSIS II A.G.T.I YEAR II ELECTRICAL POWER ENGINEERING -1- EP 02011, ELECTRICAL ENGINEERING CIRCUIT ANALYSIS II SAMPLE QUESTIONS CHAPTER 1 UNITS, DEFINITIONS, EXPERIMENTAL LAWS, AND SIMPLE CIRCUITS 1*. Determine ix and vx in each of the following circuits: 18 V RA 12 A 5A 5Ω 8Ω vx 6Ω ix 4Ω 10Ω 60 V (a) 2*. 2Ω v x ix (b) (a) Find the voltage, current, and power associated with each element in the following circuit. 12 0A 30 A 30 S 15 S (b) Determine the values of v and power absorbed by the independent current source. ix 6kΩ 3*. 2i x v 24mA 2kΩ What is the correct reading of an ohmmeter if this instrument is attached to the -2network of the following figure at points: (a) ac;(b) ab;(c) cd? 50Ω 25Ω b 16Ω 30Ω c 15Ω 4*. 7Ω a 4Ω d 12Ω In the following circuit: (a) use resistance combination methods to find Req; (b) use current division to find i1; I find i2; (d) find v3. i1 2Ω 40Ω i2 12 0mA 5**. 125Ω 50Ω 240Ω R eq 20Ω v3 Determine Gin for each network shown in the following Figures. Values are all given in millisiemens. Gin 0.8 5 50 3 2.5 4 Gin 2 0.5 100 40 6 1.5 25 ( a) 6**. 30 (b) Use current and voltage division on the following circuit to find an expression for (a) v2; (b) v1; (c) i4. R3 R1 i4 v1 VS 7**. R2 v2 R4 (a) Let vx = 10 V and find Is; (b) let Is = 50 A and find vx; (c) calculate -3the ratio vx/Is. 2Ω IS 1Ω 4Ω 5Ω v X 3Ω 8***. Use current and voltage division to obtain an expression for v5. R2 VS R1 R4 R5 R3 v5 9***. Find the power absorbed by each source of the following Figure. To what value should the 4 V source be changed to reduce the power supplied by the -5 A source to zero? -5 A 2V 3A -4 A 4V ************************ 12 A -3 V -4CHAPTER 2 SOME USEFUL TECHNIQUES OF CIRCUIT ANALYSIS 1*. Determine the values of the unknown node-to-reference voltages in the following circuit. v2 2Ω vX 0.5Ω 14 A 0.5v X 12 V Ref v1 vy 2.5Ω 1Ω v3 0.2v y v4 2*. Use mesh analysis to determine the three unknown mesh currents in the following circuit. 1Ω 7V i1 i2 3Ω 6V i3 2Ω 3*. 2Ω 1Ω Apply superposition to the following circuit and find i3. 30 Ω 8A 50Ω 30 Ω i3 100 V 60Ω 60 V -5- 4*. (a) Find iL and the power supplied by the 4 A source. (b) Transform the practical current source (8 Ω, 4 A) into a practical voltage source, and find iL and the power supplied by the new ideal voltage source. (c) What value of RL will absorb the maximum power, and what is the value of that power? iL R L 2Ω 8Ω 6V 5*. 4A (a) Find the The'venin equivalent of the following two-terminal network: 50 Ω 0.2vab 200 Ω 0.01v ab 100 Ω a v ab b (b) Find the Norton equivalent of the network shown in the following Figure: a 50 Ω 100 Ω v1 200 Ω 0.1v1 b 6**. How many trees may be connected for the following circuit? Draw a suitable tree. And also determine i3 and power of the dependent source. -65Ω 8Ω i3 25 V 7**. 12Ω 9A 10 i3 (a) Determine the The'venin equivalent at terminals a and b for the following network. How much power would be delivered to a resistor connected to a and b if Rab equals (b) 50 Ω; (c) 12.5 Ω? 10Ω 50 V a 100 V 25Ω 15Ω b ` 8**. Use source transformation and resistance combination to simplify the following Figure (a) and (b) until only two elements remain to the left of terminals a and b. 120 cos 400 t V 60Ω 10Ω 120Ω 6kΩ a 50Ω 2kΩ b ( a) 9**. 3kΩ 3.5kΩ 20mA a 12kΩ b (b) From the following circuit;(a) determine the value of RL which a maximum power can be delivered, and (b) calculate the voltage across RL (+ reference at top). 20Ω 10 i1 i1 RL 40Ω 50 V 10***. Determine the The'venin equivalent circuit for terminals: (a) aa';(b) bb' and (c) cc'. -77Ω a a' 10Ω 3Ω b b' 20Ω 2A 50 V c c' 11***. Construct a suitable tree for the following circuit and assign tree-branch voltages. Write KCL and control equations, and find i2. 50Ω v3 i2 5 i2 45Ω 30Ω 0.02v1 100 V 20Ω v1 0.2 v3 12***. Construct a tree for the circuit shown in the following Figure in which i1 and i2 are link currents. Write loop equations and solve for i1. 10 A 3Ω 240 V i1 6Ω 12Ω 30Ω ********************** i2 60 V -8CHAPTER 3 INDUCTANCE AND CAPACITANCE 1*. (a) Waveform of the current in a 3H inductor is shown in Figure, determine the inductor voltage and sketch it. i(t) (A) 1 t(s) −1 0 1 2 3 (b) Find the inductor voltage that results from applying the current waveform shown in the following Figure. i(t) (A) 1 −1 t(s) 0 − 0.1 2*. 1 2 3 2.1 (a) Suppose that the voltage across a 2H inductor is known to be 6 cos 5t V. What information is then available about the inductor current? (b) Find the maximum energy stored in the inductor of the following Figure. How much energy is dissipated in the resistor in the time during which the energy is being stored and recovered in the inductor? 0.1Ω πt 12sin A 6 3H -9- 3**. (a) Determine the maximum energy stored in the capacitor and energy dissipated in the resistor over the interval 0 ≤ t ≤ 0.5 s . 100 sin 2π tV 20µF 1MΩ AC (b) Write nodal equations for the following circuit. L vS 4**. C1 v1 iL v2 R C2 iS (a) Find Leq for the following network. 0.4 µ H L eq 1µ H 7µ H 5µ H 0.8µ H 12 µ H 5µ H 2µ H (b) Find Ceq for the following network. 0.4µ F Ceq 1µ F 7µ F 5µ F 0.8µ F 12 µ F 5µ F 2µ F ****************** - 10 CHAPTER 7 THE SINUSOIDAL FORCING FUNCTION 1. A sine wave,f(t), is zero and increasing at t =2.1 ms and the succeeding positive maximum of 8.5 occurs at t =7.5 ms. Express the wave in the from f(t) equals (a) C1 sin(ωt + φ), where φ is positive, as small as possible, and in degrees; (b) C2 cos (ωt + β), where β has the smallest possible magnitude and is in degrees; (c) C3 cos ωt + C4 sin ωt. 2. (a) If -10 cos ωt + 4sin ωt = A cos(ωt + φ), where A > 0 and -180° < φ ≤ 180°, find A and φ. (b) If 200 cos (5t + 130°) = F cos 5t + G sin 5t, find F and G. (c) Find three values of t, 0 ≤ t ≤ 1 s, at which i(t) = 5 cos 10t - 3 sin 10t = 0. (d) In what time interval between t = 0 and t = 10 ms is 10 cos 100πt ≥ 12 sin 100πt? 3. Given the two sinusoidal waveforms, f(t) = -50 cos ωt - 30 sin ωt and g(t) = 55 cos ωt -15 sin ωt , find (a) the amplitude of each, and (b) the phase angle by which f(t) leads g(t). 4. Carry out the exercise threatened in the text by substituting the assumed current response of Eq. (3), i(t) = A cos (ωt - θ), directly in the differential equation, L(di/dt) + Ri = Vm cos ωt, to show that values for A and θ are obtained which agree with Eq.(4). 5. Let vs = 20 cos 500t V in the circuit of Fig. 7.8. After simplifying the circuit a little, find iL(t). Figure 7-8 6. If is = 0,4 cos 500t A in the circuit show in Fig. 7.9, simplify the circuit until it is in the form of Fig. 7.4 and then find (a) iL(t); (b) ix(t). Figure 7-9 - 11 7. A sinuoidal voltage source vs = 100cos 105t V, a 500 ohm resistor, and an 8 mH inductor are in series. Determine those instants of time, 0 ≤ t < ½ T, at which zero power is being:(a) delivered to the resistor; (b) delivered to the inductor; (c) generated by the source. 8. In the circuit of Fig. 7.10, let vs = 3 cos 105t V and is = 0.1 cos 105t A. After making use of superposition and Thevenin's theorem, find the instantaneous values of iL and vL at t = 10 µs. Figure 7-10 9. Find iL(t) in the circuit show in Fig. 7.11. Figure 7-11 10. Both voltage sources in the circuit of Fig. 7.12 are given by 120 cos 120πt V. (a) Find an expression for the instantaneous energy stored in the inductor, and (b) use it to find the average value of the stored energy. Figure 7-12 - 12 11. In the circuit of Fig. 7.12, the voltage sources are vs1 = 120 cos 400t V and vs2 = 180 cos 200t V. Find the downward inductor current. 12. Assume that the op-amp in Fig. 7.13 is ideal (Ri = ∞, R0 = 0, and A = ∞). Note also that the integrator input has two signals applied to it, -Vm cos ωt and vout. If the product R1C1 is set equal to the ratio L/R in the circuit of Fig. 7.4, show that vout equals the voltage across R ( + reference on the left) in Fig. 7.4. Figure 7-13 13. A voltage source Vm cos ωt, a resistor R, and a capacitor C are all in series. (a) Write an integrodifferential equation in terms of the loop current i and then differentiate it to obtain the differential equation for the circuit, (b) Assume a suitable general form for the forced response i(t),substitude it in the differential equation, and determine the exact form of the forced response. ******************************** - 13 CHAPTER 8 THE PHASOR CONCEPT 1*. (a) Find the complex voltage across the series combination of a 500 Ω resistor and a 95 mH inductor if the complex current 8 ej3000t mA flows through the two elements in series. (b) Transform the time-domain voltage v(t) = 100 cos (400 t - 30º) into the frequency domain. 2*. (a) Transform each of the following functions of time into Phasor form: (i) -5 sin (580t - 110º); (ii) 3 cos 600t-5sin (600t + 110º); (iii) 8 cos (4 t- 30º) + 4 sin (4t - 100 º). (b) Find the current i(t) in the following circuit: 1.5kΩ i(t) 40sin 3000tV AC 3**. 1kΩ 1 H 3 1 µF 6 Determine the admittance (in rectangular form) of (a) an impedance Z = 1000 + j 400 Ω; (b) a network consisting of the parallel combination of an 800Ω resistor, a 1 mH inductor, and a 2 nF capacitor, if ω = 1 M rad/s ; (c) a network consisting of the series combination of an 800Ω resistor, a 1 mH inductor, and a 2 nF capacitor, if ω = 1 M rad/s . ****************** - 14 CHAPTER 9 THE SINUSOIDAL STEADY-STATE RESPONSE 1*. Determine the time-domain node voltages v1(t) and v2(t) in the following circuit. - j5Ω v1 v2 ο 1∠0 A - j10Ω 5Ω 2*. j5Ω 10Ω 0.5∠ − 90ο A Determine the time-domain currents i1 and i2 in the following circuit. 10cos103 tV AC 3**. j10Ω 500µ F 3Ω i1 4m H i 2 2 i1 Use superposition and find V1 in the following Figure. Also find the The'venin equivalent faced by the parallel combination of – j5 Ω capacitor and j10 Ω inductor. - j5Ω v1 v2 ο 1∠0 A 5Ω - j10Ω j10Ω j5Ω 10Ω 0.5∠ − 90ο A 4**. Construct plots of the amplitude and phase of Zin versus ω for the following circuit. 0 .1 H Zin 0.1 F ****************** 1 H 40 - 15 CHAPTER 10 AVERAGE POWER AND RMS VALUES 1*. (a) Time-domain voltage ,v is 4 cos (πt/6) V. Find the power relationships that result when the corresponding Phasor voltage v = 4 ∠ 0º V is applied across an impedance Z = 2 ∠60° Ω. (b) Find the average power being delivered to an impedance ZL = 8- j11Ω by a current I = 5 ∠20°A. 2*. (a) Find the average power absorbed by each of the three passive elements and the average power supplied by each source. - j2Ω j2Ω 20∠0ο V 10∠0ο V 2Ω (b) Find the average powers delivered to a 4Ω resistor by the current i1 = 2 cos 10 t – 3 cos 20 t A and i2 = 2 cos 10t – 3 cos 10 t A. 3**. (a) Calculate the average power delivered to each of the two loads, the apparent power supplied by the source, and the power factor of the combined loads. 60∠0ο Vrms 2 − j1Ω 1 + j5Ω (b) An industrial consumer is operating a 50 kW (67.1 hp) induction motor at 0.8 PF, lagging. The source voltage is 230 V rms. In order to obtain lower electrical rates, the consumer wish to raise the PF to 0.95 lagging. Specify an arrangement by which may be done. ****************** - 16 CHAPTER 11 POLYPHASE CIRCUITS 1*. A balanced 3-phase system has a line voltage = 300 V rms and supplying a balanced Y-connected load with 1200 W at a leading PF of 0.8. What are the line current and the per-phase load impedance? If 600 W lighting load is added (in parallel) to the system, determine the line current and power generated by the source. 2*. Determine the amplitude of the line current in a 300 V rms, 3-phase system which supplies 1200 W to a ∆ connected load at a lagging PF of 0.8. When load is changed to Y connection, find the phase impedance. 3**. Determine the power delivered to each of the three loads and the power lost in the neutral wire and each of the two lines. 1Ω ο 115∠0 Vrms 50Ω 20Ω 100Ω j10Ω 3Ω 115∠0ο Vrms 1Ω 4***. In the following Figure, add 1.5Ω resistance to each of the two outer lines, and 2.5Ω resistance to the neutral wire. Find the average power delivered to each of the three loads. 1Ω 115∠0ο Vrms 50Ω 20Ω 100Ω j10Ω 3Ω 115∠0ο Vrms 1Ω ****************** - 17 CHAPTER 14 MAGNETICALLY COUPLED CIRCUITS 1*. Determine the output voltage across the 400 Ω resistor to the source voltage. M =9H 1Ω V1 = 10∠0ο V 1H ω =10 rad/s 2*. 100 H 400Ω v2 Write the correct set of equations for the following circuit. 5Ω V1 1F 7H 6H 3Ω M =2H 3**. Find the T equivalent and Π equivalent of the linear shown in the following: 40mH 30 m H 6 0 mH ****************** - 18 CHAPTER 15 GENERAL TWO-PART NETWORKS 1*. Calculate the input impedance of the following network. And use admittance matrix to again find the input impedance. 20Ω 5Ω 10Ω v1 2*. 1Ω 2Ω 4Ω (a) Find the input impedance. 0.5I a 5Ω 1Ω 10Ω v1 2Ω Ia 4Ω (b) Find the four short-circuit admittance parameters for the resistive two-port. 10Ω v1 3**. I1 5Ω I2 20Ω v2 In an approximate linear equivalent of a transistor amplifier, the emitter is the bottom node, the base is the upper input node and the collector is the upper output node. 2000 Ω resistor is connected between the collector and base. Determine the performance of the amplifier. 4***. Find [z] for the two-port shown in the following: - 19 50Ω 20Ω v1 25Ω 50Ω 20Ω v2 40Ω v1 ( a) 25Ω (b) 5***. Find [h] for the two-port shown in the following: 20Ω v1 10Ω 40Ω v2 v1 40Ω ( a) v2 (b) 6***. Find [h] for the two-port shown in the following: 6Ω v1 12Ω 10Ω 12Ω v2 ( a) v1 2I 2 10Ω I2 (b) ************************** Note : * ** *** Must Know Questions Should Know Questions Could Know Questions v2 v2 - 20 -